Numerical Data

Numerical data in DynamicalSystems.jl is most often represented by a structure called Dataset

#DelayEmbeddings.Dataset — Type.

Dataset{D, T} <: AbstractDataset{D,T}

A dedicated interface for datasets. It contains equally-sized datapoints of length D, represented by SVector{D, T}.

When indexed with 1 index, a dataset is like a vector of datapoints.

When indexed with 2 indices it behaves like a matrix that has each of the columns be the timeseries of each of the dynamic variables.

Description of indexing

In the following let i, j be integers, typeof(data) <: AbstractDataset and v1, v2 be <: AbstractVector{Int} (v1, v2 could also be ranges).

• data[i] gives the ith datapoint (returns an SVector)
• data[v1] will return a vector of datapoints
• data[v1, :] using a Colon as a second index will return a Dataset of these points
• data[:, j] gives the jth variable timeseries, as Vector
• data[v1, v2] returns a Dataset with the appropriate entries (first indices being "time"/point index, while second being dynamic variables)
• data[i, j] value of the jth variable, at the ith timepoint

Use Matrix(dataset) or Dataset(matrix) to convert. It is assumed that each column of the matrix is one dynamic variable. If you have various timeseries vectors x, y, z, ... pass them like Dataset(x, y, z, ...). You can use columns(dataset) to obtain the reverse, i.e. all columns of the dataset in a tuple.

In essence a Dataset is simply a container for a Vector of SVectors. However, it is visually represented as a matrix, similarly to how numerical data would be printed on a spreadsheet (with time being the column direction). It also offers a lot more functionality than just pretty-printing. Besides the examples in the documentation string, you can also do:

using DynamicalSystems
hen = Systems.henon()
data = trajectory(hen, 10000) # this returns a dataset
for point in data
# do stuff with each datapoint
# (vector with as many elements as system dimension)
end

Most functions from DynamicalSystems.jl that manipulate and use data are expecting an AbstractDataset subtype. This allows us to define efficient methods that coordinate well with each other, like e.g. neighborhood.

If given a matrix, we first convert to Dataset. This means that you should first convert your data to a Dataset if you want to call functions more than once, to avoid constantly converting.

Dataset Functions

Functions that operate on datasets.

#DelayEmbeddings.minima — Function.

minima(dataset)

Return an SVector that contains the minimum elements of each timeseries of the dataset.

#DelayEmbeddings.maxima — Function.

maxima(dataset)

Return an SVector that contains the maximum elements of each timeseries of the dataset.

#DelayEmbeddings.minmaxima — Function.

minmaxima(dataset)

Return minima(dataset), maxima(dataset) without doing the computation twice.

#DelayEmbeddings.columns — Function.

columns(dataset) -> x, y, z, ...

Return the individual columns of the dataset.

Dataset I/O

Input/output functionality for an AbstractDataset is already achieved using base Julia, specifically writedlm and readdlm.

The thing to note is that all data of an AbstractDataset is contained within its field data.

To write and read a dataset, simply do:

using DelimitedFiles

data = Dataset(rand(1000, 2))

# I will write and read using delimiter ','
writedlm("data.txt", data.data, ',')

# Don't forget to convert the matrix to a Dataset when reading
data = Dataset(readdlm("data.txt", ',', Float64))

Neighborhoods in a dataset

Combining the excellent performance of NearestNeighbors.jl with the AbstractDataset allows us to define a function that calculates a "neighborhood" of a given point, i.e. finds other points near it. The different "types" of the neighborhoods are subtypes of AbstractNeighborhood.

#DelayEmbeddings.neighborhood — Function.

neighborhood(point, tree, ntype)
neighborhood(point, tree, ntype, n::Int, w::Int = 1)

Return a vector of indices which are the neighborhood of point in some data, where the tree was created using tree = KDTree(data [, metric]). The ntype is the type of neighborhood and can be any subtype of AbstractNeighborhood.

Use the second method when the point belongs in the data, i.e. point = data[n]. Then w stands for the Theiler window (positive integer). Only points that have index abs(i - n) ≥ w are returned as a neighborhood, to exclude close temporal neighbors. The default w=1 is the case of excluding the point itself.

References

neighborhood simply interfaces the functions knn and inrange from NearestNeighbors.jl by using the argument ntype.

#DelayEmbeddings.AbstractNeighborhood — Type.

AbstractNeighborhood

Supertype of methods for deciding the neighborhood of points for a given point.

Concrete subtypes:

• FixedMassNeighborhood(K::Int) : The neighborhood of a point consists of the K nearest neighbors of the point.
• FixedSizeNeighborhood(ε::Real) : The neighborhood of a point consists of all neighbors that have distance < ε from the point.

See neighborhood for more.